Dr Jamila EL Medany. By the end of the lecture the student should be able to: List the components of the fetal membranes. Describe the stages of development.

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Presentation on theme: "Dr Jamila EL Medany. By the end of the lecture the student should be able to: List the components of the fetal membranes. Describe the stages of development."— Presentation transcript:

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Dr Jamila EL Medany

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By the end of the lecture the student should be able to: List the components of the fetal membranes. Describe the stages of development of the components. Describe the structure and function of the components. Describe their fate and the possible congenital anomalies. By the end of the lecture the student should be able to: List the components of the fetal membranes. Describe the stages of development of the components. Describe the structure and function of the components. Describe their fate and the possible congenital anomalies.

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It is attached to a point near the centre of the fetal surface of the placenta

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(1) Abnormal Attachment: a-Battledore placenta : The UC is attached to the margin of the placenta (it is not dangerous). b-Velamentous insertion of the cord : UC is attached to the amnion away from placenta, (It is dangerous to the fetus due to liability of rupture of its blood vessels during labor) (1) Abnormal Attachment: a-Battledore placenta : The UC is attached to the margin of the placenta (it is not dangerous). b-Velamentous insertion of the cord : UC is attached to the amnion away from placenta, (It is dangerous to the fetus due to liability of rupture of its blood vessels during labor)

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(2) Abnormalities in Length: a-Very Long Cord: It is dangerous, it may prolapse or coil around the fetus. Prolapsed cord is compressed during labor causing fetal hypoxia or anoxia. If the deficiency of oxygen persists for more than five minutes, the baby’ brain may be damaged producing mental retardation. b-Very Short Cord: It is dangerous because it may cause premature separation of placenta, or the cord itself may rupture (2) Abnormalities in Length: a-Very Long Cord: It is dangerous, it may prolapse or coil around the fetus. Prolapsed cord is compressed during labor causing fetal hypoxia or anoxia. If the deficiency of oxygen persists for more than five minutes, the baby’ brain may be damaged producing mental retardation. b-Very Short Cord: It is dangerous because it may cause premature separation of placenta, or the cord itself may rupture

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(3) knots of umbilical cord: a-False knots: Normally the UC looks tortuous due to twisting of umbilical vessels (umbilical vessels are longer than the cord), these knots are normal and do not cause any harm to the fetus b-True knots: Are rare (1%) of pregnancy, but very dangerous because they may cause obstruction to blood flow in umbilical vessels, leading to fetal death resulting from fetal anoxia. (3) knots of umbilical cord: a-False knots: Normally the UC looks tortuous due to twisting of umbilical vessels (umbilical vessels are longer than the cord), these knots are normal and do not cause any harm to the fetus b-True knots: Are rare (1%) of pregnancy, but very dangerous because they may cause obstruction to blood flow in umbilical vessels, leading to fetal death resulting from fetal anoxia. True Knots in 20-weeks fetus

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Appears in the Blastocyst stage at 10-days, it lies ventral to the embryonic plate. Its roof :hypoblast (primary endoderm), Its wall :exocoelomic membrane, (lines the inner surface of the cytotrophoblast), Appears in the Blastocyst stage at 10-days, it lies ventral to the embryonic plate. Its roof :hypoblast (primary endoderm), Its wall :exocoelomic membrane, (lines the inner surface of the cytotrophoblast),

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After folding, part of Yolk Sac is enclosed within the embryo to form the Gut (Foregut, Midgut & Hindgut). The remainder of Yolk Sac that remains outside the embryo becomes the Definitive Yolk Sac  The midgut is temporarily connected to Definitive Yolk Sac by a narrow duct Vitello-intestinal duct (Yolk stalk), which is incorporated inside the umbilical cord After folding, part of Yolk Sac is enclosed within the embryo to form the Gut (Foregut, Midgut & Hindgut). The remainder of Yolk Sac that remains outside the embryo becomes the Definitive Yolk Sac  The midgut is temporarily connected to Definitive Yolk Sac by a narrow duct Vitello-intestinal duct (Yolk stalk), which is incorporated inside the umbilical cord

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 At 3 rd week:  (a) Blood formation  first formed in the extra- embryonic mesoderm covering the wall of the yolk sac, until hemopoietic activity begins in the liver during 6 th week  At 3 rd week:  (a) Blood formation  first formed in the extra- embryonic mesoderm covering the wall of the yolk sac, until hemopoietic activity begins in the liver during 6 th week (b)Primordial germ cells in the endodermal lining of the wall of caudal end of the yolk sac migrate into the developing sex glands to differentiate into germ cells (spermatogonia or oogonia)  At 4 th week: endoderm of yolk sac is incorporated into the embryo as the primitive gut.  Its endoderm gives rise to the epithelium of the Respiratory &Digestive tracts.  At 4 th week: endoderm of yolk sac is incorporated into the embryo as the primitive gut.  Its endoderm gives rise to the epithelium of the Respiratory &Digestive tracts.

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 YolkStalk detached from midgut by the end of 6 th week.  In (2%) of adults, its proximal intra- abdominal part persists as Ileal diverticulum (Meckel’s Diverticulum).  At week (10): small definitive yolk sac lies in the chorionic cavity between amniotic & chorionic sacs  At week (20):, as pregnancy advances, definitive yolk sac atrophies and becomes a very small cyst.  In unusual cases, it persists under the amnion near the attachment of Umbilical cord, on the fetal surface of the placenta. Its persistence is of no significance  YolkStalk detached from midgut by the end of 6 th week.  In (2%) of adults, its proximal intra- abdominal part persists as Ileal diverticulum (Meckel’s Diverticulum).  At week (10): small definitive yolk sac lies in the chorionic cavity between amniotic & chorionic sacs  At week (20):, as pregnancy advances, definitive yolk sac atrophies and becomes a very small cyst.  In unusual cases, it persists under the amnion near the attachment of Umbilical cord, on the fetal surface of the placenta. Its persistence is of no significance

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 At 3 rd week (day 16):  Appears as a diverticulum from caudal wall of YS that extends into the connecting stalk.  At 2 nd month: Its extra- embryonic part degenerates.  At 3 rd month: Its intra- embryonic part extends from UB to UC as a thick tube, ‘(Urachus) ’  After birth: the Urachus is obliterated and fibrosed to form Median Umbilical Ligament, that extends from apex of UB to umbilicus.  At 3 rd week (day 16):  Appears as a diverticulum from caudal wall of YS that extends into the connecting stalk.  At 2 nd month: Its extra- embryonic part degenerates.  At 3 rd month: Its intra- embryonic part extends from UB to UC as a thick tube, ‘(Urachus) ’  After birth: the Urachus is obliterated and fibrosed to form Median Umbilical Ligament, that extends from apex of UB to umbilicus.

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 It is a thin, transparent & tough fluid- filled, membranous sac surrounding the embryo.  At First : It is seen as a small cavity lying Dorsal to the embryonic plate.  At Stage of Chorionic Vesicle: The amnion becomes separated from the chorion by Chorionic Cavity (extra embryonic coelom).  After Folding: the amnion expands greatly and is becomes on the ventral surface of the embryo.  As a result of expansion of the amnion, the extra embryonic coelom is gradually obliterated and amnion forms the epithelial covering of umbilical cord.  It is a thin, transparent & tough fluid- filled, membranous sac surrounding the embryo.  At First : It is seen as a small cavity lying Dorsal to the embryonic plate.  At Stage of Chorionic Vesicle: The amnion becomes separated from the chorion by Chorionic Cavity (extra embryonic coelom).  After Folding: the amnion expands greatly and is becomes on the ventral surface of the embryo.  As a result of expansion of the amnion, the extra embryonic coelom is gradually obliterated and amnion forms the epithelial covering of umbilical cord.

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It is a watery fluid inside the amniotic cavity (sac). It has a major role in fetal growth & development It increases slowly, to become ( ) ml by full term (37) weeks. Composition: 99% of amniotic fluid is water It contains un-dissolved material of desquamated fetal epithelial cells + organic + inorganic salts As pregnancy advances, composition of amniotic fluid changes as fetal excreta (meconium = fetal feces/& urine) are added It is a watery fluid inside the amniotic cavity (sac). It has a major role in fetal growth & development It increases slowly, to become ( ) ml by full term (37) weeks. Composition: 99% of amniotic fluid is water It contains un-dissolved material of desquamated fetal epithelial cells + organic + inorganic salts As pregnancy advances, composition of amniotic fluid changes as fetal excreta (meconium = fetal feces/& urine) are added

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Maternal source: 1-Diffusion across amnio- chorionic membrane at the decidua parietalis. 2-Diffusion across chorionic plate from the maternal blood in the intervillous spaces of the placenta. Later, it is derived from Fetal source : Skin, Fetal Respiratory tract & Mostly by Excreting Urine (at beginning of 11 th week)

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Provides symmetrical external growth of the embryo Acts as a barrier to infection (it is an aseptic medium) Permits normal fetal lung development Prevents adherence of embryo to amnion Protects embryo against external injuries Keeps the fetal body temperature constant Allows the embryo to move freely, aiding muscular development in the limbs Maintain homeostasis of fluids & electrolytes Permits studies on fetal enzymes, hormones and diagnosis of fetal sex and chromosomal abnormalities Provides symmetrical external growth of the embryo Acts as a barrier to infection (it is an aseptic medium) Permits normal fetal lung development Prevents adherence of embryo to amnion Protects embryo against external injuries Keeps the fetal body temperature constant Allows the embryo to move freely, aiding muscular development in the limbs Maintain homeostasis of fluids & electrolytes Permits studies on fetal enzymes, hormones and diagnosis of fetal sex and chromosomal abnormalities

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Amniotic fluid remains constant & in balance --Most of fluid is swallowed by fetus, and absorbed into fetal respiratory and digestive tracts, where it is metabolised -- Part of fluid passes through placental membrane into maternal blood capillaries in intervillus space, Other part of fluid is excreted by fetal kidneys and returned to the amniotic sac through the fetal urinary tract. Amniotic fluid remains constant & in balance --Most of fluid is swallowed by fetus, and absorbed into fetal respiratory and digestive tracts, where it is metabolised -- Part of fluid passes through placental membrane into maternal blood capillaries in intervillus space, Other part of fluid is excreted by fetal kidneys and returned to the amniotic sac through the fetal urinary tract.